/* SPDX-License-Identifier: LGPL-2.1-or-later */ /*** Copyright © 2014 Axis Communications AB. All rights reserved. ***/ #include #include #include #include #include #include "sd-ipv4acd.h" #include "alloc-util.h" #include "arp-util.h" #include "ether-addr-util.h" #include "event-util.h" #include "fd-util.h" #include "in-addr-util.h" #include "memory-util.h" #include "network-common.h" #include "random-util.h" #include "siphash24.h" #include "string-table.h" #include "string-util.h" #include "time-util.h" /* Constants from the RFC */ #define PROBE_WAIT_USEC (1U * USEC_PER_SEC) #define PROBE_NUM 3U #define PROBE_MIN_USEC (1U * USEC_PER_SEC) #define PROBE_MAX_USEC (2U * USEC_PER_SEC) #define ANNOUNCE_WAIT_USEC (2U * USEC_PER_SEC) #define ANNOUNCE_NUM 2U #define ANNOUNCE_INTERVAL_USEC (2U * USEC_PER_SEC) #define MAX_CONFLICTS 10U #define RATE_LIMIT_INTERVAL_USEC (60U * USEC_PER_SEC) #define DEFEND_INTERVAL_USEC (10U * USEC_PER_SEC) typedef enum IPv4ACDState { IPV4ACD_STATE_INIT, IPV4ACD_STATE_STARTED, IPV4ACD_STATE_WAITING_PROBE, IPV4ACD_STATE_PROBING, IPV4ACD_STATE_WAITING_ANNOUNCE, IPV4ACD_STATE_ANNOUNCING, IPV4ACD_STATE_RUNNING, _IPV4ACD_STATE_MAX, _IPV4ACD_STATE_INVALID = -EINVAL, } IPv4ACDState; struct sd_ipv4acd { unsigned n_ref; IPv4ACDState state; int ifindex; int fd; char *ifname; unsigned n_iteration; unsigned n_conflict; sd_event_source *receive_message_event_source; sd_event_source *timer_event_source; usec_t defend_window; struct in_addr address; /* External */ struct ether_addr mac_addr; sd_event *event; int event_priority; sd_ipv4acd_callback_t callback; void *userdata; sd_ipv4acd_check_mac_callback_t check_mac_callback; void *check_mac_userdata; }; #define log_ipv4acd_errno(acd, error, fmt, ...) \ log_interface_prefix_full_errno( \ "IPv4ACD: ", \ sd_ipv4acd, acd, \ error, fmt, ##__VA_ARGS__) #define log_ipv4acd(acd, fmt, ...) \ log_interface_prefix_full_errno_zerook( \ "IPv4ACD: ", \ sd_ipv4acd, acd, \ 0, fmt, ##__VA_ARGS__) static const char * const ipv4acd_state_table[_IPV4ACD_STATE_MAX] = { [IPV4ACD_STATE_INIT] = "init", [IPV4ACD_STATE_STARTED] = "started", [IPV4ACD_STATE_WAITING_PROBE] = "waiting-probe", [IPV4ACD_STATE_PROBING] = "probing", [IPV4ACD_STATE_WAITING_ANNOUNCE] = "waiting-announce", [IPV4ACD_STATE_ANNOUNCING] = "announcing", [IPV4ACD_STATE_RUNNING] = "running", }; DEFINE_PRIVATE_STRING_TABLE_LOOKUP_TO_STRING(ipv4acd_state, IPv4ACDState); static void ipv4acd_set_state(sd_ipv4acd *acd, IPv4ACDState st, bool reset_counter) { assert(acd); assert(st < _IPV4ACD_STATE_MAX); if (st != acd->state) log_ipv4acd(acd, "%s -> %s", ipv4acd_state_to_string(acd->state), ipv4acd_state_to_string(st)); if (st == acd->state && !reset_counter) acd->n_iteration++; else { acd->state = st; acd->n_iteration = 0; } } static void ipv4acd_reset(sd_ipv4acd *acd) { assert(acd); (void) event_source_disable(acd->timer_event_source); acd->receive_message_event_source = sd_event_source_disable_unref(acd->receive_message_event_source); acd->fd = safe_close(acd->fd); ipv4acd_set_state(acd, IPV4ACD_STATE_INIT, true); } static sd_ipv4acd *ipv4acd_free(sd_ipv4acd *acd) { assert(acd); ipv4acd_reset(acd); sd_event_source_unref(acd->timer_event_source); sd_ipv4acd_detach_event(acd); free(acd->ifname); return mfree(acd); } DEFINE_TRIVIAL_REF_UNREF_FUNC(sd_ipv4acd, sd_ipv4acd, ipv4acd_free); int sd_ipv4acd_new(sd_ipv4acd **ret) { _cleanup_(sd_ipv4acd_unrefp) sd_ipv4acd *acd = NULL; assert_return(ret, -EINVAL); acd = new(sd_ipv4acd, 1); if (!acd) return -ENOMEM; *acd = (sd_ipv4acd) { .n_ref = 1, .state = IPV4ACD_STATE_INIT, .ifindex = -1, .fd = -EBADF, }; *ret = TAKE_PTR(acd); return 0; } static void ipv4acd_client_notify(sd_ipv4acd *acd, int event) { assert(acd); if (!acd->callback) return; acd->callback(acd, event, acd->userdata); } int sd_ipv4acd_stop(sd_ipv4acd *acd) { IPv4ACDState old_state; if (!acd) return 0; old_state = acd->state; ipv4acd_reset(acd); if (old_state == IPV4ACD_STATE_INIT) return 0; log_ipv4acd(acd, "STOPPED"); ipv4acd_client_notify(acd, SD_IPV4ACD_EVENT_STOP); return 0; } static int ipv4acd_on_timeout(sd_event_source *s, uint64_t usec, void *userdata); static int ipv4acd_set_next_wakeup(sd_ipv4acd *acd, usec_t usec, usec_t random_usec) { usec_t next_timeout, time_now; assert(acd); next_timeout = usec; if (random_usec > 0) next_timeout += (usec_t) random_u64() % random_usec; assert_se(sd_event_now(acd->event, CLOCK_BOOTTIME, &time_now) >= 0); return event_reset_time(acd->event, &acd->timer_event_source, CLOCK_BOOTTIME, time_now + next_timeout, 0, ipv4acd_on_timeout, acd, acd->event_priority, "ipv4acd-timer", true); } static int ipv4acd_on_timeout(sd_event_source *s, uint64_t usec, void *userdata) { sd_ipv4acd *acd = ASSERT_PTR(userdata); int r = 0; switch (acd->state) { case IPV4ACD_STATE_STARTED: acd->defend_window = 0; ipv4acd_set_state(acd, IPV4ACD_STATE_WAITING_PROBE, true); if (acd->n_conflict >= MAX_CONFLICTS) { log_ipv4acd(acd, "Max conflicts reached, delaying by %s", FORMAT_TIMESPAN(RATE_LIMIT_INTERVAL_USEC, 0)); r = ipv4acd_set_next_wakeup(acd, RATE_LIMIT_INTERVAL_USEC, PROBE_WAIT_USEC); } else r = ipv4acd_set_next_wakeup(acd, 0, PROBE_WAIT_USEC); if (r < 0) goto fail; break; case IPV4ACD_STATE_WAITING_PROBE: case IPV4ACD_STATE_PROBING: /* Send a probe */ r = arp_send_probe(acd->fd, acd->ifindex, &acd->address, &acd->mac_addr); if (r < 0) { log_ipv4acd_errno(acd, r, "Failed to send ARP probe: %m"); goto fail; } log_ipv4acd(acd, "Probing "IPV4_ADDRESS_FMT_STR, IPV4_ADDRESS_FMT_VAL(acd->address)); if (acd->n_iteration < PROBE_NUM - 2) { ipv4acd_set_state(acd, IPV4ACD_STATE_PROBING, false); r = ipv4acd_set_next_wakeup(acd, PROBE_MIN_USEC, (PROBE_MAX_USEC-PROBE_MIN_USEC)); if (r < 0) goto fail; } else { ipv4acd_set_state(acd, IPV4ACD_STATE_WAITING_ANNOUNCE, true); r = ipv4acd_set_next_wakeup(acd, ANNOUNCE_WAIT_USEC, 0); if (r < 0) goto fail; } break; case IPV4ACD_STATE_ANNOUNCING: if (acd->n_iteration >= ANNOUNCE_NUM - 1) { ipv4acd_set_state(acd, IPV4ACD_STATE_RUNNING, false); break; } _fallthrough_; case IPV4ACD_STATE_WAITING_ANNOUNCE: /* Send announcement packet */ r = arp_send_announcement(acd->fd, acd->ifindex, &acd->address, &acd->mac_addr); if (r < 0) { log_ipv4acd_errno(acd, r, "Failed to send ARP announcement: %m"); goto fail; } log_ipv4acd(acd, "Announcing "IPV4_ADDRESS_FMT_STR, IPV4_ADDRESS_FMT_VAL(acd->address)); ipv4acd_set_state(acd, IPV4ACD_STATE_ANNOUNCING, false); r = ipv4acd_set_next_wakeup(acd, ANNOUNCE_INTERVAL_USEC, 0); if (r < 0) goto fail; if (acd->n_iteration == 0) { acd->n_conflict = 0; ipv4acd_client_notify(acd, SD_IPV4ACD_EVENT_BIND); } break; default: assert_not_reached(); } return 0; fail: sd_ipv4acd_stop(acd); return 0; } static bool ipv4acd_arp_conflict(sd_ipv4acd *acd, const struct ether_arp *arp, bool announced) { assert(acd); assert(arp); /* RFC 5227 section 2.1.1. * "the host receives any ARP packet (Request *or* Reply) on the interface where the probe is * being performed, where the packet's 'sender IP address' is the address being probed for, * then the host MUST treat this address as being in use by some other host" */ if (memcmp(arp->arp_spa, &acd->address, sizeof(struct in_addr)) == 0) return true; if (announced) /* the TPA matched instead of SPA, this is not a conflict */ return false; /* "any ARP Probe where the packet's 'target IP address' is the address being probed for, and * the packet's 'sender hardware address' is not the hardware address of any of the host's * interfaces, then the host SHOULD similarly treat this as an address conflict" */ if (arp->ea_hdr.ar_op != htobe16(ARPOP_REQUEST)) return false; /* not ARP Request, ignoring. */ if (memeqzero(arp->arp_spa, sizeof(struct in_addr)) == 0) return false; /* not ARP Probe, ignoring. */ if (memcmp(arp->arp_tpa, &acd->address, sizeof(struct in_addr)) != 0) return false; /* target IP address does not match, BPF code is broken? */ if (acd->check_mac_callback && acd->check_mac_callback(acd, (const struct ether_addr*) arp->arp_sha, acd->check_mac_userdata) > 0) /* sender hardware is one of the host's interfaces, ignoring. */ return false; return true; /* conflict! */ } static void ipv4acd_on_conflict(sd_ipv4acd *acd) { assert(acd); acd->n_conflict++; log_ipv4acd(acd, "Conflict on "IPV4_ADDRESS_FMT_STR" (%u)", IPV4_ADDRESS_FMT_VAL(acd->address), acd->n_conflict); ipv4acd_reset(acd); ipv4acd_client_notify(acd, SD_IPV4ACD_EVENT_CONFLICT); } static int ipv4acd_on_packet( sd_event_source *s, int fd, uint32_t revents, void *userdata) { sd_ipv4acd *acd = ASSERT_PTR(userdata); struct ether_arp packet; ssize_t n; int r; assert(s); assert(fd >= 0); n = recv(fd, &packet, sizeof(struct ether_arp), 0); if (n < 0) { if (ERRNO_IS_TRANSIENT(errno) || ERRNO_IS_DISCONNECT(errno)) return 0; log_ipv4acd_errno(acd, errno, "Failed to read ARP packet: %m"); goto fail; } if ((size_t) n != sizeof(struct ether_arp)) { log_ipv4acd(acd, "Ignoring too short ARP packet."); return 0; } switch (acd->state) { case IPV4ACD_STATE_ANNOUNCING: case IPV4ACD_STATE_RUNNING: if (ipv4acd_arp_conflict(acd, &packet, true)) { usec_t ts; assert_se(sd_event_now(acd->event, CLOCK_BOOTTIME, &ts) >= 0); /* Defend address */ if (ts > acd->defend_window) { acd->defend_window = ts + DEFEND_INTERVAL_USEC; r = arp_send_announcement(acd->fd, acd->ifindex, &acd->address, &acd->mac_addr); if (r < 0) { log_ipv4acd_errno(acd, r, "Failed to send ARP announcement: %m"); goto fail; } log_ipv4acd(acd, "Defending "IPV4_ADDRESS_FMT_STR, IPV4_ADDRESS_FMT_VAL(acd->address)); } else ipv4acd_on_conflict(acd); } break; case IPV4ACD_STATE_STARTED: case IPV4ACD_STATE_WAITING_PROBE: case IPV4ACD_STATE_PROBING: case IPV4ACD_STATE_WAITING_ANNOUNCE: if (ipv4acd_arp_conflict(acd, &packet, false)) ipv4acd_on_conflict(acd); break; default: assert_not_reached(); } return 0; fail: sd_ipv4acd_stop(acd); return 0; } int sd_ipv4acd_set_ifindex(sd_ipv4acd *acd, int ifindex) { assert_return(acd, -EINVAL); assert_return(ifindex > 0, -EINVAL); assert_return(acd->state == IPV4ACD_STATE_INIT, -EBUSY); acd->ifindex = ifindex; return 0; } int sd_ipv4acd_get_ifindex(sd_ipv4acd *acd) { if (!acd) return -EINVAL; return acd->ifindex; } int sd_ipv4acd_set_ifname(sd_ipv4acd *acd, const char *ifname) { assert_return(acd, -EINVAL); assert_return(ifname, -EINVAL); if (!ifname_valid_full(ifname, IFNAME_VALID_ALTERNATIVE)) return -EINVAL; return free_and_strdup(&acd->ifname, ifname); } int sd_ipv4acd_get_ifname(sd_ipv4acd *acd, const char **ret) { int r; assert_return(acd, -EINVAL); r = get_ifname(acd->ifindex, &acd->ifname); if (r < 0) return r; if (ret) *ret = acd->ifname; return 0; } int sd_ipv4acd_set_mac(sd_ipv4acd *acd, const struct ether_addr *addr) { int r; assert_return(acd, -EINVAL); assert_return(addr, -EINVAL); assert_return(!ether_addr_is_null(addr), -EINVAL); acd->mac_addr = *addr; if (!sd_ipv4acd_is_running(acd)) return 0; assert(acd->fd >= 0); r = arp_update_filter(acd->fd, &acd->address, &acd->mac_addr); if (r < 0) { ipv4acd_reset(acd); return r; } return 0; } int sd_ipv4acd_detach_event(sd_ipv4acd *acd) { assert_return(acd, -EINVAL); acd->event = sd_event_unref(acd->event); return 0; } int sd_ipv4acd_attach_event(sd_ipv4acd *acd, sd_event *event, int64_t priority) { int r; assert_return(acd, -EINVAL); assert_return(!acd->event, -EBUSY); if (event) acd->event = sd_event_ref(event); else { r = sd_event_default(&acd->event); if (r < 0) return r; } acd->event_priority = priority; return 0; } int sd_ipv4acd_set_callback(sd_ipv4acd *acd, sd_ipv4acd_callback_t cb, void *userdata) { assert_return(acd, -EINVAL); acd->callback = cb; acd->userdata = userdata; return 0; } int sd_ipv4acd_set_check_mac_callback(sd_ipv4acd *acd, sd_ipv4acd_check_mac_callback_t cb, void *userdata) { assert_return(acd, -EINVAL); acd->check_mac_callback = cb; acd->check_mac_userdata = userdata; return 0; } int sd_ipv4acd_set_address(sd_ipv4acd *acd, const struct in_addr *address) { int r; assert_return(acd, -EINVAL); assert_return(address, -EINVAL); assert_return(in4_addr_is_set(address), -EINVAL); if (in4_addr_equal(&acd->address, address)) return 0; acd->address = *address; if (!sd_ipv4acd_is_running(acd)) return 0; assert(acd->fd >= 0); r = arp_update_filter(acd->fd, &acd->address, &acd->mac_addr); if (r < 0) goto fail; r = ipv4acd_set_next_wakeup(acd, 0, 0); if (r < 0) goto fail; ipv4acd_set_state(acd, IPV4ACD_STATE_STARTED, true); return 0; fail: ipv4acd_reset(acd); return r; } int sd_ipv4acd_get_address(sd_ipv4acd *acd, struct in_addr *address) { assert_return(acd, -EINVAL); assert_return(address, -EINVAL); *address = acd->address; return 0; } int sd_ipv4acd_is_running(sd_ipv4acd *acd) { if (!acd) return false; return acd->state != IPV4ACD_STATE_INIT; } int sd_ipv4acd_is_bound(sd_ipv4acd *acd) { assert_return(acd, false); return IN_SET(acd->state, IPV4ACD_STATE_ANNOUNCING, IPV4ACD_STATE_RUNNING); } int sd_ipv4acd_start(sd_ipv4acd *acd, bool reset_conflicts) { int r; assert_return(acd, -EINVAL); assert_return(acd->event, -EINVAL); assert_return(acd->ifindex > 0, -EINVAL); assert_return(in4_addr_is_set(&acd->address), -EINVAL); assert_return(!ether_addr_is_null(&acd->mac_addr), -EINVAL); assert_return(acd->state == IPV4ACD_STATE_INIT, -EBUSY); r = sd_event_get_state(acd->event); if (r < 0) return r; if (r == SD_EVENT_FINISHED) return -ESTALE; r = arp_network_bind_raw_socket(acd->ifindex, &acd->address, &acd->mac_addr); if (r < 0) return r; close_and_replace(acd->fd, r); if (reset_conflicts) acd->n_conflict = 0; r = sd_event_add_io(acd->event, &acd->receive_message_event_source, acd->fd, EPOLLIN, ipv4acd_on_packet, acd); if (r < 0) goto fail; r = sd_event_source_set_priority(acd->receive_message_event_source, acd->event_priority); if (r < 0) goto fail; (void) sd_event_source_set_description(acd->receive_message_event_source, "ipv4acd-receive-message"); r = ipv4acd_set_next_wakeup(acd, 0, 0); if (r < 0) goto fail; ipv4acd_set_state(acd, IPV4ACD_STATE_STARTED, true); return 0; fail: ipv4acd_reset(acd); return r; }